Hostname: page-component-848d4c4894-m9kch Total loading time: 0 Render date: 2024-05-22T09:17:48.027Z Has data issue: false hasContentIssue false
  • English
  • Français

BRCA1/2 Variant Data-Sharing Practices

Published online by Cambridge University Press:  01 January 2021

Juli M. Bollinger ,
Abhi Sanka ,
Lena Dolman ,
Rachel G. Liao  and
Robert Cook-Deegan
Rights & Permissions [Opens in a new window]

Abstract

Accessing BRCA1/2 data facilitates the detection of disease-associated variants, which is critical to informing clinical management of risks. BRCA1/2 data sharing is complex and many practices exist. We describe current BRCA1/2 data-sharing practices, in the United States and globally, and discuss obstacles and incentives to sharing, based on 28 interviews with personnel at U.S. and non-U.S. clinical laboratories and databases. Our examination of the BRCA1/2 data-sharing landscape demonstrates strong support for and robust sharing of BRCA1/2 data around the world, increasing global accesses to diverse data sets.

Type
Symposium Articles
Information
Journal of Law, Medicine & Ethics , Volume 47 , Issue 1: Sharing Data in a Medical Information Commons , Spring 2019 , pp. 88 - 96
Copyright
Copyright © American Society of Law, Medicine and Ethics 2019

The breast cancer susceptibility genes BRCA1 and BRCA2 were identified and sequenced in 1994 and 1995, respectively. Individuals identified as harboring a pathogenic variant in BRCA1 or BRCA2 are at a significantly elevated lifetime risk of developing breast and ovarian cancer and face treatment choices ranging from prophylactic surgery to increased surveillance.Reference Miki, Swenson, Shattuck-Eidens and Futreal1 After two decades of BRCA1/2 testing, however, new variants continue to be discovered. Interpreting the significance of new variants relies upon data sharing among the generators and holders of BRCA1/2 data.

BRCA1/2 variant data sharing originated in the research context in the mid 1990's, even as the BRCA genes were being identified. Early efforts included the Breast Information Core (BIC), part of the U.S. National Human Genome Research Institute (NHGRI; then named the National Center for Human Genome Research), and the International Agency for Research on Cancer, part of the World Health Organization (WHO).Reference Cheon, Mozersky and Cook-Deegan2 The advent of commercial testing for BRCA1 and BRCA2 in 1996 shifted the bulk of BRCA1/2 variant generation out of research laboratories and into the clinical context. Early commercial testing for BRCA1/2 was limited to a few laboratories in the U.S., Australia, and Europe. Myriad Genetics' patent on BRCA1/2 testing, and subsequent fear of patent liability following the 1997 patent enforcement against Oncormed and the University of Pennsylvania resulted in Myriad becoming, for all intents and purposes, the exclusive provider of commercial BRCA1/2 testing in the United States until June 2013. Despite strong patent rights in many countries, the Myriad patent was largely ignored in most countries outside the U.S.Reference Van Zimmerman, Nicol, Gold, Carbone, Gibbon, Joseph, Mozerksy, zur Nieden and Palfner3 In addition, despite its participation in early, public data-sharing efforts, Myriad, the single largest contributor of variant data to BIC, ceased sharing its BRCA1/2 variant data with BIC in late 2004.Reference Hawkins4 This move, coupled with its patent-based U.S. service monopoly on BRCA1/2 testing, allowed Myriad to accumulate the largest proprietary database of BRCA1/2 variants anywhere in the world.

In 2013, the U.S. Supreme Court overturned the patent-eligibility of patents on DNA molecules whose sequence is found in nature.5 In the immediate aftermath of the Supreme Court decision, several U.S. laboratories began offering BRCA1/2 testing or announced plans to do so. Furthermore, advances in high-throughput sequencing technologies, plummeting sequencing costs, and rapid adoption of clinical sequencing into clinical care led to an increased number of laboratories offering large, multi-gene panels for inherited risks of cancer, panels that included testing for BRCA1/2 variants. Beginning in 2013, a growing number of clinical laboratories began generating large amounts of BRCA1/2 genomic variant data. In parallel, ClinVar, an open-access database of the National Library of Medicine in the United States, was established in 2013 as an open variant database for all genes.Reference Landrum, Lee, Benson and Brown6 And that same year, the newly formed Global Alliance for Genomics and Health (GA4GH) declared the BRCA Challenge a flagship project to enable sharing of data about BRCA1/2 variants, leading to establishment of the BRCA Exchange, an open-access data resource with clinically-vetted information on over 20,000 BRCA1/2 variants.7

Despite strong patent rights in many countries, the Myriad patent was largely ignored in most countries outside the U.S. In addition, despite its participation in early, public data-sharing efforts, Myriad, the single largest contributor of variant data to BIC, ceased sharing its BRCA1/2 variant data with BIC in late 2004. This move, coupled with its patent-based U.S. service monopoly on BRCA1/2 testing, allowed Myriad to accumulate the largest proprietary database of BRCA1/2 variants anywhere in the world.

Many laboratories and databases that generate and house BRCA1/2 variant data are located outside of the United States. Data from populations outside North America and Europe are likely sources of new variants, as founder mutations have been well documented in many different populations that are not common in Europe and North America, where genetic testing is most common. Variants common in countries where testing is more prevalent are likely to have been discovered and would be found in current databases, but testing is limited in many world populations and hence these populations may well harbor variants that have eluded detection.Reference Fernandes, Michelli, Galvão and Paula8 Furthermore, studies have shown the prevalence of BRCA1/2 variants, including variants of unknown significance, differ by race/ethnicity.Reference Hall, Reid, Stat and Burbridge9 Today, BRCA1/2 clinical testing can be interpreted approximately 95% of the time (i.e., 5% VUS rate) in individuals of North European ancestry with lower interpretation rates for other groups.Reference Ready, Gutierrez-Barrera, Amos and Meric-Bernstam10 In other parts of the world, however, the fraction of variants whose clinical significance is not yet known is significantly higher in non-whites. Ensuring the bidirectional flow of data between world regions with established and emerging clinical sequencing will be critical to accumulate the volume of data necessary to determine the statistical and clinical significance of new variants.

Here we describe current BRCA1/2 data-sharing practices in the U.S. and globally, as described in interviews with academic and commercial clinical laboratories (8 U.S., 10 non-U.S.) and databases (2 U.S. and 8 non-U.S.). We address the data-sharing practices among laboratories and databases, identify incentives and barriers to BRCA1/2 data sharing, and highlight the resources clinical laboratories reported using to interpret the clinical significance of BRCA1/2 variants.

Methods

The data presented here were collected under two separate, but parallel efforts: one focused on BRCA1/2 data sharing in the U.S., the other focused on BRCA1/2 data sharing from laboratories and databases outside the United States. The U.S. analysis was led by researchers at Arizona State University and Baylor College of Medicine, while the analysis of non-U.S. efforts was led by collaborators at GA4GH at the Broad Institute in Cambridge, MA. While the two research “sub-teams” (i.e., the “U.S. team” and the “non-U.S. team”) collected data independently, they met weekly throughout the project to develop project materials and discuss findings. The U.S. interviews were conducted under a protocol for semi-structured interviews approved by and IRB at the Baylor College of Medicine and exempted by the IRB at Arizona State University. The non-U.S. survey was done as a work product, leveraging the existing contacts of the GA4GH, BRCA Challenge, and BRCA Exchange.

Semi-structured interviews were conducted with representatives of U.S. clinical laboratories (both academic and commercial) generating BRCA1/2 variant data and databases that house such variant data. Interviews with representatives of U.S. laboratories and databases occurred between August and December 2017. Phone and email-based interviews were conducted with key personnel from laboratories and databases from 15 countries across North America, South America, Europe, Africa, the Middle East, and Asia. These interviews were conducted between November 2017 and February 2018.

Sample Selection

U.S. laboratories and databases were identified by searching for laboratories offering BRCA1/2 testing using the Genetic Testing Registry, reviewing the list of BRCA1/2 variant data submitters listed on the ClinVar Website, and through Google and PubMed searches.11 Non-U.S. laboratories and databases were identified through Genetic Test Registry, as well as by our colleagues at GA4GH (including suggestions from leadership of the BRCA Challenge project) as many of the representatives of these entities are currently working with, or have plans to work with, GA4GH. The list of potential interviewees collected was not exhaustive. By design, invitations were preferentially directed to the laboratories and databases generating and storing the larger volumes of BRCA1/2 variant data. More specifically, invitations were extended to commercial laboratories known to provide the bulk of BRCA1/2 testing in the United States, including those known to share BRCA1/2 variant data and those known to not share data.

Potential interviewees were sent an emailed invitation to participate in a project interview or were already known contacts in non-U.S. databases and labs. U.S. interviewees opted to participate via telephone or videoconference. Non-U.S. interviewees agreed to a telephone interview or returned answers to the interview questions via email.

Data Collection

U.S. interviewees expressed verbal consent to participate in an audio-recorded interview. Each interview was conducted by two project team members: an interviewer and a dedicated note-taker. Non-U.S. interviewees expressed verbal consent to participate in an interview or responded to email inquiries. Each interview was conducted by a project team member. To facilitate a more nuanced discussion and systematic exploration of major themes, four semi-structured interview guides were developed: a U.S. laboratory interview guide, a non-U.S. laboratory interview guide, a U.S. database interview guide, and a non-U.S. database guide. All four guides included a core set of questions regarding BRCA1/2 variant data-sharing practices, resources used when interpreting new variants, and incentives and barriers to BRCA1/2 data sharing.

In order to increase willingness to participate in an interview and to foster an open discussion, interviewees were assured that (1) their name and the name of the institution they represented would remain confidential and (2) their answers to our questions would be considered not for attribution, unless they provided explicit permission for public attribution.

Data Analysis

U.S. Interviews

Responses from the data collection forms were entered into an Excel spreadsheet in order to analyze responses across all interviews. Two members of the U.S. research team reviewed the data collection forms and Excel data and independently developed a list of themes that emerged through the interviews. The research team met as a group to discuss the themes identified and resolve any discrepancies.

Non-U.S. Interviews

Responses from the data collection forms were entered into an Excel spreadsheet in order to analyze responses across all interviews. Two members of the U.S. research team and both members of the non-U.S. team reviewed their respective data to discuss the themes identified and resolve any discrepancies in interview interpretation. Non-U.S. interviewees were also provided with a written summary of the interview and provided the opportunity to clarify answers or correct inaccuracies (which was particularly helpful for those individuals whose first language was not English). A detailed report summarizing the results from the non-U.S. laboratory and database interviews was provided to the U.S. project team [Online Supplementary Material: public version of the GA4GH report].

Results

Twenty-two invitations for an interview were extended to 19 clinical laboratories (academic and commercial) offering BRCA1/2 testing and three databases collecting BRC1/2A variant information based in the U.S. Representatives from eight laboratories and two databases agreed to participate in an interview (response rate 47.6%). Four interviews included more than one interviewee for total of 17 participants.

The report on non-U.S. BRCA1/2 data sharing was based on responses from 10 clinical laboratories (academic and commercial) and 8 databases, representing fifteen countries in North-America, South America, Europe, Africa, the Middle East and Asia (Figure 1). Five interviews included more than one interviewee, for a total of 23 participants.

Figure 1 Map Displaying 15 Non-U.S. Countries Represented

Summary of BRCA1/2 Testing and Sharing Practices

U.S. clinical laboratories reported an average of six years of experience with BRCA1/2 testing. Of the eight laboratories interviewed, all but one laboratory began offering BRCA1/2 testing after the Myriad patent was overturned in 2013. One laboratory reported 15 years of experience with BRCA1/2 testing, having paid a royalty to Myriad for approximately 10 years prior to the patent being invalidated. In contrast, the non-U.S. laboratories reported an average length of experience with testing for BRCA1/2 of 10 years (range 1-22 years).

Resources Used to Interpret New Variants

All 18 laboratories interviewed were asked to specify which resources they routinely access during the process of BRCA1/2 variant interpretation. Both U.S. and non-U.S. laboratories reported using a number of resources when interpreting BRCA1/2 variants. Resources cited included in-house databases, genomic variant databases (ClinVar, LOVD, ARUP, etc.), population databases (ExAC, gnomAD, 1000 Genomes, etc.), commercial or paid access databases (ThermoFisher's BRCA OncomineTM database, UMD/BRCAShareTM, HGMD, SOPHiA Genetics, etc.), as well as literature (PubMed, OMIM) and Google searches (Table 1).

Table 1 Resources Routinely Used by Laboratories

Overwhelmingly, both U.S. and non-U.S. laboratories favored the use of publicly available resources. In both groups, ClinVar was the most commonly used genomic variant database and was considered by many as the “go-to” resource. Four factors appeared to drive ClinVar's favorability: (1) ClinVar represented a centralization of multiple data sources. Many of the disease- and locus-specific databases that were historically consulted when interpreting a variant now contribute their data to ClinVar (e.g. BIC, ARUP, LOVD, etc.); (2) The amount of variant data housed in ClinVar and the number of laboratories and databases submitting data to ClinVar continues to grow; (3) ClinVar displays the basis of evidence for clinical interpretation, and is linked to the ClinGen network of experts; (4) ClinVar uses the standard reporting categories for genomic variants. These categories have been recommended by the American College of Medical Genetics and Genomics and the Association for Molecular Pathology and the European Society for Human Genetics.Reference Richards, Aziz, Bale and Bick12 A few U.S. interviewees expected that the amount of BRCA1/2 variant data in ClinVar would soon rival, if not surpass, Myriad's proprietary database. Finally, (5) ClinVar is free and publicly available and allows unfettered use of its data. One U.S. interviewee commented that they no longer consult the pay-for-access resource, BRCAShare, because “[we] can get the same data from ClinVar.”

Both U.S. and non-U.S. laboratories consistently relied upon publicly-accessible population databases when interpreting new BRCA1/2 variants. While ExAC, gnomAD, and 1000 Genomes were commonly cited resources, gnomAD was gaining favor as the preferred population database. These databases were largely used to assess allele frequency, and were preferred because of their size, the quality of curation, and their open science ethos, with free availability and unfettered use. Only a few laboratories reported using the BRCA Exchange database (3 U.S., 1 non-U.S.).

While laboratory personnel both in the U.S. and abroad are utilizing a growing number of online database resources when interpreting BRCA1/2 variants, our interviews reveal that they also continue to employ more traditional methods including: reviewing their own in-house data collections, reaching out to colleagues, and conducting literature searches using PubMed, Google Scholar, or other tools for surveying the medical and scientific literature.

Interviews with both U.S. and non-U.S. laboratory personnel revealed several common themes:

  • Preference for publicly available databases.

  • Aversion to pay-for-access or proprietary databases.

  • A preference for resources that are easy to access and navigate, and comprehensive resources (i.e. avoidance of having to query numerous datasets).

  • Preference for databases that compile information from other resources.

  • Preference for ability to determine how variants were classified and aversion to databases that lack clarity on data quality, data submitters, and how interpretations were made.

  • Preferred datasets that are updated regularly.

  • Preferences for databases that draw from large, ethnically diverse populations.

BRCA Data-Sharing Practices

All eight U.S. clinical laboratories reported sharing BRCA1/2 variant data with ClinVar. Five of the laboratories shared the variant data with ClinVar exclusively, three shared data with ENIGMA, and two reported sharing some data directly with BRCA Exchange (but note that ClinVar and ENIGMA both share data with BRCA Exchange). The majority of laboratories reported sharing BRCA1/2 data shortly after the inception of ClinVar in 2013.

While all of the U.S. laboratories interviewed reported sharing variant data with ClinVar, the type of information and level of detail varied. Descriptions of the BRCA1/2 variant information shared included: (1) “everything seen”; (2) “formally classified” variants; (3) Sanger-confirmed variants; (4) variants observed at least once before; and (5) only variants with interpretation.

The fact that ClinVar is a publicly-available resource was the key factor in its emergence as the primary vehicle for sharing BRCA1/2 variant data in the U.S. Interviewees explained that putting variant data into the public domain not only honored their belief in the importance of sharing data freely and broadly, it also minimized the logistical burdens associated with contributing variant data to multiple places. By depositing variant data into a public database, one interviewee explained, they can direct all inquiries for data to the ClinVar database. All eight U.S. laboratories reported having multiple personnel involved in the data-sharing process including database managers, curators, bioinformaticians, engineers, clinical variant specialists, laboratory personnel, and genetic counselors.

In contrast, six of the ten non-U.S. laboratories interviewed reported sharing BRCA1/2 data. Four non-U.S. laboratories are currently not sharing data: three of these laboratories planned to begin sharing in the future and one did not have plans to share data but was open to the idea of sharing in the future. Among the six laboratories currently sharing data, three contribute to CIMBA, two share their data with ClinVar, two with LOVD, and two with ENIGMA. One laboratory reported sharing with the Breast Cancer Association Consortium (BCAC), Asian BRCA Consortium (ABRCA), and BIC. Laboratories sharing BRCA1/2 data reported having done so for different durations, ranging from 1 to 20 years.

The most frequently shared data were variants alongside their interpretations or associated evidence (i.e., publications). One laboratory shared pedigrees and penetrance data, and another shared case-level (i.e., with information about individual cases) and clinical or epidemiological research data. None of the non-U.S. laboratories reported having dedicated staff devoted exclusively to data sharing; the task was typically shared among team members and/or laboratory leadership.

Incentives for Sharing

The majority of U.S-based laboratories described a strong sense of duty to share BRCA1/2 variant data. Interviewees described a belief that data sharing was “the right thing to do,” part of their “clinical duty,” and demonstrated their “commitment to patient health-care.” Many stated that data sharing was critical to advancing scientific progress, improving patient care, and ultimately benefiting the quality of their field overall. Interviewees expressed a strong aversion to data hoarding (“I have no patience for that”) and keeping data sequestered in silos. Furthermore, interviewees from U.S. laboratories described a growing expectation, or as one interviewee put it, a “pressure,” to share data within the genetics/genomics community. One interviewee observed that laboratories did not want to be seen as not sharing.

Non-U.S. laboratories had less to report when asked about incentives and motivations for sharing BRCA1/2 data. The most commonly cited incentive for sharing was the existence of supportive collaborators/peers/community with which to share. Other incentives mentioned more than once included the existence of tools to initiate sharing/make the process easier, and a sense that sharing improves the quality of work for all involved (e.g., stronger variant interpretations and emergence of community-supported best practices). Finally, data sharing was seen as meeting patient expectations, supporting patient autonomy (e.g., in the case of returning results directly to patients), and helping the community.

Barriers to Sharing

When asked about barriers to BRCA1/2 data sharing, all interviewees (both U.S. and non-U.S.) cited personnel-related burdens, most commonly the lack of dedicated staff. Interviewees commonly described the process of sharing/submitting data as a time-consuming, burdensome task that was distributed among a variety of laboratory personnel (and in addition to their regular job responsibilities). Other barriers cited by more than half of all interviewees included a lack of time for data-sharing activities and the associated financial/budget/cost burdens (e.g., an inability to recoup costs, uncompensated personnel time/effort). Two U.S-based-laboratories mentioned receiving some financial relief through ClinVar/ClinGen grants.

Given that all of the U.S. laboratories interviewed are submitting data to ClinVar, the technical challenges mentioned were specific to the ClinVar submission process: the lack of an API interface, a cumbersome and time-consuming submission process, and the need to extract and format data prior to submission because ClinVar currently takes data only in Excel spreadsheet format, requiring submitters to reformat their data. Several laboratory representatives recounted acute technical challenges when beginning/implementing sharing data with ClinVar, but they reported that many of these challenges have been ameliorated over time.

Our examination of the BRCA1/2 data-sharing landscape demonstrates strong support for and robust sharing of BRCA1/2 data around the world, increasing global accesses to diverse data sets. All U.S. laboratories and databases and the majority of the non-U.S. laboratories interviewed reported sharing at least a subset of their BRCA1/2 variant data with public databases, though the amount and type of information varied. There was general consensus about the value of sharing to support both variant classification and well-informed clinical decision-making.

Among the non-U.S. laboratories sharing BRCA1/2-variant data, five additional barriers were mentioned: technical constraints, liability concerns, lack of education/awareness about available databases for sharing, competitive incentives to keep data, and a lack of sharing culture. Among the four non-U.S. laboratories not currently sharing BRCA1/2 variant data, additional barriers were mentioned: institutional barriers (needing permission from multiple levels of the institution), logistical concerns over maintaining data sovereignty (e.g., to avoid potential misappropriation or exploitation of local patient data by other world regions), national laws and procedures requiring approval for data export, and potential inability to get patient consent (due to lack of available counselling services, low regional patient literacy rates, and patient fears regarding insurance discrimination).

Experience Hosting BRCA1/2 Data in a Shareable/Accessible Context

The ten interviewed databases (2 U.S., 8 non-U.S.) are each hosted in a way that enables sharing in an online context, at least among consortium members and many allowing open access. The databases interviewed varied with respect to age, size, access, and level of curation. The oldest databases interviewed were established in the mid-1990s, before the advent of commercial BRCA1/2 testing, while other resources started as recently as the past 1-2 years. Databases that launched in the 1990s reported more total variants than those that launched more recently. Databases cited collections of unique BRCA1/2 variants ranging from a few hundred to several thousands. Access constraints varied among the databases, with some allowing full access, some requiring registration, and others being closed except to participating national consortium members. In addition, databases provided variable levels of curation, including none at all, submitter-based, formal vetting and clinical interpretation by ENIGMA, or relying on specific contexts.

Discussion

Our examination of the BRCA1/2 data-sharing landscape demonstrates strong support for and robust sharing of BRCA1/2 data around the world, increasing global accesses to diverse data sets. All U.S. laboratories and databases and the majority of the non-U.S. laboratories interviewed reported sharing at least a subset of their BRCA1/2 variant data with public databases, though the amount and type of information varied. There was general consensus about the value of sharing to support both variant classification and well-informed clinical decision-making.

While the value of sharing data was reported in both the U.S. and non-U.S. interviews, it was most strongly expressed in the interviews with U.S. laboratories and databases. U.S. interviewees reported being motivated to share data by an ethical obligation, clinical duty, and service to the greater good. Many explicitly expressed strong anti-data-hoarding sentiments. Likely this asymmetry can be attributed to the impact of the Myriad patents and resulting service monopoly on BRCA1/2 testing in the U.S. Myriad's decision to cease contributing BRCA1/2 variant data to the public database BIC in 2004, and instead sequester its data in a proprietary database, has likely further fueled a strong anti-data-hoarding sentiment among other U.S. laboratories and databases. In contrast, most countries outside the U.S. largely ignored Myriad's patents and testing was not impeded.

Despite strong support for data sharing worldwide, our interviews also revealed the fragility of a sharing norm. Both U.S. and non-U.S. laboratories and databases reported significant financial, technical, and logistical barriers and unreimbursed costs of preparing data to be shared, personnel time and effort required to share data, and associated technical infrastructure costs. In addition, interviewees with non-U.S. laboratories and databases reported other substantive barriers to data sharing including issues of data sovereignty, legal and liability issues (one country reported sharing data across borders is illegal), and a lack of a supportive, sharing culture.

In general, interviewees expressed a preference for publicly-accessible, freely-available, comprehensive databases as well as those that are easy to access and navigate. The databases ClinVar, ExAc, and gnomAD were the most commonly cited publicly-available resources. Our interviews show a consolidation of data-sharing efforts, with ClinVar emerging as the leading resource used for interpreting and sharing BRCA1/2 variant data. ClinVar appears to be becoming a “one-stop-shop” for clinical interpretation and deposit of genomic variant data. Interviewees repeatedly attributed ClinVar's appeal to its public and open-access status. ClinVar's role as central resource minimized the burdens of consulting with and submitting data to multiple resources, while ensuring data are in the public domain. Many of the databases historically consulted when interpreting BRCA1/2 variants (e.g., BIC, LOVD, etc.) prior to the creation of ClinVar in 2014 now submit their data to ClinVar. However, it is important to note that in light of some the substantive, and in some cases intractable, barriers to the flow of data (particularly) internationally, it is likely that there will not be a single, central location for depositing BRCA1/2 variant data. Rather, data will need to remain in place and methods and tools for accessing data developed.Reference Bollinger, Zuk, Majumder and Versalovic13 GA4GH is actively working on development of such standards and tools.14

It is noteworthy that all eight of the U.S. laboratories interviewed reported sharing BRCA1/2 variant data compared to slightly more than half of the laboratories (6/10) outside the U.S. This finding likely reflects a selection bias in the U.S. sample. Laboratories currently sharing BRCA1/2 data were more willing to agree to participate in an interview about BRCA1/2 data sharing. However, this finding may also reflect the fact that in the U.S., data sharing has been strongly promoted in the National Institutes of Health (NIH) and many scientific and medical journals have implemented policies that ensure publications rest on evidence that can be verified. In addition, in the United States, small grants from ClinVar/ClinGen are available to assist small laboratories off-set costs associated with submitting data to ClinVar.

Acknowledgements

The authors thank the interview participants, as well as Mary A. Majumder at the Center for Medical Ethics and Health Policy at the Baylor College of Medicine in Houston, TX. This work was supported by grant number R01 HG008918 (AMG and RCD) from National Institutes of Health, National Human Genome Research Institute. The views expressed in this article are solely those of the authors.

Footnotes

Additionally, Dr. Liao reports other from GA4GH and personal fees from UCSC, outside the submitted work.

References

Miki, Y., Swenson, J., Shattuck-Eidens, D., and Futreal, P.A. et al., “A Strong Candidate for the Breast and Ovarian Cancer Susceptibility Gene BRCA1,” Science 266, no. 5182 (1994): 66-71, available at <https://doi.org/10.1126/science.7545954> (last visited January 16, 2019); R. Wooster, G. Bignell, J. Lancaster, and S. Swift et al., “Identification of the Breast Cancer Susceptibility Gene BRCA2,” Nature 378 (1995): 789-792, available at <https://doi.org/10.1038/378789a0> (last visited January 16, 2019); S.M. Domcheck and B.L. Weber, “Clinical Management of BRCA1 and BRCA2 Mutation Carriers,” Oncogene 25 (2006): 5825-5831, available at <https://doi.org/10.1038/sj.onc.1209881> (last visited January 16, 2019).CrossRefGoogle Scholar
Cheon, J.Y., Mozersky, J., and Cook-Deegan, R., “Variants of Uncertain Significance in BRCA: A Harbinger of Ethical and Policy Issues to Come?” Genetics in Medicine 6, no. 12 (2014): 121, available at <https://doi.org/10.1186/s13073-014-0121-3> (last visited January 16, 2019).Google Scholar
For more information on the impact of BRCA patents, see Van Zimmerman, E., Nicol, D., Gold, E.R., and Carbone, J., “The BRCA Patent Controversies: An International Review of Patent Disputes,” in Gibbon, S., Joseph, G., Mozerksy, J., zur Nieden, A., and Palfner, S., Eds., Breast Cancer Gene Research and Medical Practices: Transnational Perspectives in the Time of BRCA (Oxford, UK and New York, NY: Routledge, 2014): at 151-174. See also S. Parthasarathy, Building Genetic Medicine: Breast Cancer, Technology, and the Comparative Politics of Healthcare (Boston: MIT Press, 2007); S. Parthasarathy, Patent Politics: Life Forms, Markets, and the Public Interest in the United States and Europe (Chicago: The University of Chicago Press, 2017), J.M. Conley, R. Cook-Deegan, and G. Lãzaro-Muñoz, “Myriad after Myriad: The Proprietary Data Dilemma,” North Carolina Journal of Law and Technology 15, no.4 (2014): 597-637, available at <https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4275833/> (last visited January 16, 2019).Google Scholar
Hawkins, N., “The Impact of Human Gene Patents on Genetic Testing in the United Kingdom,” Genetics in Medicine 13, no. 4 (2011): 320-324, available at <https://doi.org/10.1097/gim.0b013e3181fc50bc> (last visited January 16, 2019).CrossRefGoogle Scholar
See Association for Molecular Pathology v. Myriad Genetics Inc, 133 U.S. S. Ct. 2107 (2013).Google Scholar
Landrum, M., Lee, J.M., Benson, M., and Brown, G.R. et al., “ClinVar: Improving Access to Variant Interpretations and Supporting Evidence,” Nucleic Acids Research 46, no. D1 (2017): D1062-1067, available at <https://doi.org/10.1093/nar/gkx1153> (last visited January 16, 2019).Google Scholar
The Global Alliance for Genomics and Health, “A Federated Ecosystem for Sharing Genomic, Clinical Data,” Science 352, no. 6291 (2016): 1278-1280, available at <https://doi.org/10.1126/science.aaf6162> (last visited January 16, 2019).+(last+visited+January+16,+2019).>Google Scholar
Fernandes, G.C., Michelli, R.A.D., Galvão, H.C.R., and Paula, A. E. et al., “Prevalence of BRCA1/BRCA2 Mutations in a Brazilian Population Sample At-Risk for Hereditary Breast Cancer and Characterization of its Genetic Ancestry,” Onco-target 7, no. 49 (2016): 80465-80481, available at <https://doi.org/10.18632/oncotarget.12610> (last visited January 16, 2019).Google Scholar
Hall, M., Reid, J., Stat, M., and Burbridge, L. et al., BRCA1 and BRCA2 Mutations in Women of Different Ethnicities Undergoing Testing for Hereditary Breast-Ovarian Cancer,” Cancer 115, no. 10 (2009): 2222-2233, available at <doi: http://dx.doi.org/10.1002/cncr.24200> (last visited January 16, 2019).CrossRefGoogle Scholar
Ready, K., Gutierrez-Barrera, A.M., Amos, C., and Meric-Bernstam, F. et al., “Cancer Risk Management Decisions of Women with BRCA1 or BRCA2 Variants of Uncertain Significance,” Breast 17, no. 2 (2011): 210-212, available at <https://doi.org/10.1111/j.1524-4741.2010.01055.x> (last visited January 16, 2019); A. E. Toland, A. Forman, F. Couch, and J.O. Culver et al., “Clinical Testing of BRCA1 and BRCA2: A Worldwide Snapshot of Technological Practices,” Genomic Medicine 3, no. 7 (2018), available at <https://doi.org/10.1038/s41525-018-0046-7> (last visited January 16, 2019); A. Kurian, K.Ward, A. Hamilton, and D. Deapen et al., “Uptake, Results and Outcomes of Germline Multiple-Gene Sequencing After Diagnosis of Breast Cancer,” JAMA Oncology 4, no. 8 (2018): 1066-1072, available at <doi: http://dx.doi.org/10.1001/jamaoncol.2018.0644> (last visited January 16, 2019); J. Caswell-Jin, T. Gupta, E. Hall, and I. Petrovchich et al., “Racial/Ethnic Differences in Multi-Gene Sequencing Results for Hereditary Cancer Risk,” Genetics in Medicine 20, no. 2 (2018): 234-239, available at <doi: http://dx.doi.org/10.1038/gim.2017.96> (last visited January 16, 2019), T. Slavin, L. Van Tongeren, C. Behrendt, and I. Solomon et al., “Prospective Study of Caner Genetic Variants: Variation in Rate of Reclassification by Ancestry,” JNCI: Journal of the National Cancer Institute 110, no. 10 (2018): 1059-1066, available at <http://dx.doi.org/10.1093/jcni/djy027> (last visited January 16, 2019).CrossRefGoogle Scholar
National Center for Biotechnology Information, “Tests,” GTR: Genetic Testing Registry, available at <https://www.ncbi.nlm.nih.gov/gtr/> (last visited January 16, 2019); National Center for Biotechnology Information, “Submitter's Page,” ClinVar, available at <https://www.ncbi.nlm.nih.gov/clinvar/submitters/> (last visited January 16, 2019). (last visited January 16, 2019).' href=https://scholar.google.com/scholar?q=National+Center+for+Biotechnology+Information,+“Tests,”+GTR:+Genetic+Testing+Registry,+available+at++(last+visited+January+16,+2019);+National+Center+for+Biotechnology+Information,+“Submitter's+Page,”+ClinVar,+available+at++(last+visited+January+16,+2019).>Google Scholar
Richards, S., Aziz, N., Bale, S., and Bick, D. et al., “Standards and Guidelines for the Interpretation of Sequence Variants: A Joint Consensus Recommendations of the American College of Medical Genetics and Genomics and the Association for Molecular Pathology,” Genetics in Medicine 17, no. 5 (2015): 405-424, available at <https://doi.org/10.1038/gim.2015.30> (last visited January 16, 2019); G. Matthijs, E. Souche, A. Alders, and A. Corveleyn et al., “Guidelines for Diagnostic Next-Generation Sequencing,” European Journal of Human Genetics 24, no. 1 (2016): 2-5, available at <https://doi.org/10.1038/ejhg.2015.226> (last visited January 16, 2019).CrossRefGoogle Scholar
Bollinger, J.M., Zuk, P.D., Majumder, M.A., and Versalovic, E. et al., “What Is a Medical Information Commons?” Journal of Law, Medicine & Ethics 47, no. 1 (2019): 41-50.CrossRefGoogle Scholar
Global Alliance for Genomics and Health, “Strategic Road-map,” available at <https://www.ga4gh.org/how-we-work/strategic-roadmap/> (last visited January 16, 2019).+(last+visited+January+16,+2019).>Google Scholar
Figure 0

Figure 1 Map Displaying 15 Non-U.S. Countries Represented

Figure 1

Table 1 Resources Routinely Used by Laboratories

Supplementary material: PDF

Bollinger et al. supplementary material

Building the Medical Information Commons: Case Study on BRCA Variant Data-Sharing Practices

Download Bollinger et al. supplementary material(PDF)
PDF 427.3 KB